Mounting apparatus for electronic component

ABSTRACT

An apparatus is provided with a component feeding member for feeding electronic components having lead wires in a tape-bonded state, an insertion head for separating the electronic components fed from the feeding member from the tapes and inserting to holes of a board, and a fixing head facing the insertion head via the board for cutting and folding the lead wires of the inserted electronic component in the board thereby fixing the electronic component to the board. AC servo motors operating independently of each other are individually set in the insertion head and the fixing head, which are controlled by a device so as to be synchronous with each other.

This is a divisional application of Ser. No. 09/960,330, filed Apr. 15,1998, now U.S. Pat. No. 6,115,908, which is a continuation of Ser. No.08/605,774, filed Feb. 22, 1996, now U.S. Pat. No. 5,797,178.

BACKGROUND OF THE INVENTION

The present invention relates to an apparatus for automatically mountingelectronic components to a board, and more particularly to an apparatuswhich is adapted to insert electronic components having lead wires toholes of a board, cut and fold the lead wires and fix the electroniccomponents to the board.

In a conventional mounting apparatus of the type referred to above,there are arranged a table part for positioning a board at apredetermined position, a feeding part for feeding tape-bondedelectronic components having lead wires, an insertion head forseparating the electronic components supplied from the feeding part fromthe tapes and inserting then into holes of the board, and a fixing headopposed to the insertion head via the board for fixing the electroniccomponents to the board after cutting and folding the lead wires of theinserted electronic components. One AC servo motor is used as a drivingsource for the insertion head and the fixing head because of a necessityto synchronize both heads. The AC servo motor is connected directly withthe insertion head, but connected to the fixing head via timing pulleysand a timing belt to transmit a driving force, thereby driving bothheads synchronously. A chain and sprockets, or gears and a transmissionshaft, are used in some cases instead of the timing pulleys and thetiming belt.

The conventional apparatus will be described with reference to FIG. 4.The apparatus consists of components designated by 33-43. Morespecifically, in FIG. 4, an electronic component having lead wires issupplied from a feeding part 31 in a tape-bonded state. The electroniccomponent is separated from the tapes before the electronic component isinserted into a hole of a board 32 by an insertion head 33. A fixinghead 34 facing the insertion head 33 via the board 32 cuts and folds thelead wires of the electronic component inserted into the board, thenfixes the electronic component to the board 32. A single driving source,i.e., AC servo motor 35, applies a driving force simultaneously to theinsertion head 33 and the fixing head 34. Besides the above-describedcomponent parts, the apparatus includes a timing pulley 36 set at anoutput shaft of the AC servo motor 35, a timing pulley 37 at a drivingshaft of the fixing head 34, a timing belt 38 for transmitting a drivingforce of the timing pulley 36 to the timing pulley 37, a manual handle39 for bringing rotary encoders connected to the insertion head 33 andthe fixing head 34 to origins of the encoders after the apparatus.stops, a cam 40 as a part of the insertion head 33, a lever 41 fordriving the insertion head 33 in association with the cam 40, a cam 42as a part of the fixing head 34, and a lever 43 following the cam 42 fordriving the fixing head 34.

The above mounting apparatus operates in the following manner. First,the insertion head 33 is driven by a driving force of the AC servo motor35. The electronic component is received from the feeding part 31 andinserted into the hole of the board 32. At the same time, the drivingforce of the AC servo motor is transmitted via the timing pulleys 36, 37and timing belt 38 to drive the fixing head 34. As a result, the leadwires of the electronic component inserted to the hole of the board 32are cut and folded, and the electronic component is thus fixed to theboard 32.

The above constitution necessitates the single driving source to driveboth the insertion head 33 and the fixing head 34, generating a largerotational load. The AC servo motor 35 becomes disadvantageously bulkyin size. Moreover, a large inertia of the rotational load lengthens thetime for activating or stopping the apparatus. Further, distant shaftssuch as those of the insertion head 33 and fixing head 34 have to besimultaneously driven in an interlocking manner with the use of thetransmission component, e.g., the timing belt 38 or the like, causingthe apparatus to be complicated in structure. The amount of strokecannot be changed by an up-down mechanism consisting of the cam 42 andlever 43 in the fixing head 34, and the assembly of the up-downmechanism is hard to adjust, complicated in structure and large in size.Since a lifting part for moving the whole fixing head 34 up and down anda folding part for cutting and folding the lead wires of the electroniccomponents and fixing the electronic components to the board are drivenby one driving source, the rotational load is increased to make thedriving motor large. The inertia of the rotational load is so large thata long time is required for stopping and starting the apparatus.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a mounting apparatusfor electronic components which is simplified in structure, with adriving motor miniaturized in size, whereby a time for starting andstopping the apparatus is shortened, thereby reducing a mounting cycletime.

In accomplishing these and other aspects, according to one aspect of thepresent invention, there is provided an apparatus for mountingelectronic components, comprising an electronic component feeding memberfor feeding electronic components having lead wires in a tape-bondedwith tapes.

An insertion head inserts the lead wires of one of the electroniccomponents fed from the feeding member into holes of a board afterseparating the lead wires from the tapes.

A fixing head faces the insertion head via the board for cutting andfolding the lead wires of the electronic component inserted in the holesof the board, and fixes the electronic component to the board.

A driving source is set for each of the insertion head and the fixinghead to independently drive the corresponding head.

A synchronizing device sychronizes the driving sources.

According to another aspect of the present invention, there is providedan apparatus for mounting electronic components, comprising

an electronic component feeding member for feeding electronic componentswith lead wires in a tape-bonded state by use of tapes.

An insertion head inserts the lead wires of one of the electroniccomponents fed from the feeding member into holes of the board afterseparating the component from the tapes.

A fixing head faces the insertion head via the board for cutting andfolding the lead wires of the electronic component inserted into theholes of the board and fixes the electronic component to the board. Thefixing head includes a lifting part for moving the whole fixing head upand down and a folding part arranged inside the fixing head for cuttingand folding the lead wires of the electronic component.

A first driving motor is provided for the insertion head.

A cam is fitted at a driving shaft connected to the first driving motor,for driving the insertion head.

An encoder detects a rotating position of a rotor of the driving motor.

A second driving motor and an encoder detects a rotating position of arotor of the second driving motor, with which each of the lifting partand the folding part is equipped.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other aspects and features of the present invention willbecome clear from the following description taken in conjunction withthe preferred embodiments thereof and with reference to the accompanyingdrawings, in which:

FIG. 1 is a perspective view of a mounting apparatus for electroniccomponents according to a first embodiment of the present invention;

FIG. 2 is a perspective view of a fixing head of a mounting apparatusfor electronic components according to a second embodiment of thepresent invention;

FIG. 3 is a longitudinal sectional view of the fixing head of FIG. 2;

FIG. 4 is a prespective view of a conventional apparatus for mountingelectronic components;

FIG. 5 is a front view of electronic components with lead wires intape-bonded state;

FIG. 6 is a sectional view showing a state where an electronic componentis inserted into holes of a board by the use of an insertion head of themounting apparatus; and

FIG. 7 is a sectional view showing a state where an electronic componentis inserted into holes of a board and fixed to the board by the use ofthe insertion head and fixing head.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Before the description of the present invention proceeds, it is to benoted that like parts are designated by like reference numeralsthroughout the accompanying drawings.

A preferred embodiment of the present invention will be described withreference to the accompanying drawings.

FIG. 1 shows a first embodiment of the present invention. In FIG. 1,reference numeral 1 is a component feeding member for feeding electroniccomponents 100 with lead wires 100 a in a tape-bonded state by the useof tapes 101 as shown in FIG. 5. Reference numeral 2 is a board to whichthe electronic components 100 are mounted. Reference numeral 3 is aninsertion head separating the electronic components 100 supplied by thefeeding member 1 from the tapes 101 and inserting the lead wires 100 aof the component 100 to holes 2 a of the board 2 as shown in FIG. 6.Reference numeral 4 is an AC servo motor used as a driving source forimpressing a driving force to the insertion head 3, and is directlycoupled to a driving shaft 3 a of the insertion head 3. An encoder 5 isset at the driving shaft 3 a to detect a rotating position of the shaft3 a. Moreover, a cam 3 b, which is part of the insertion head 3 is fixedto the driving shaft 3 a. A driving lever 3 c moving the insertion head3 operates following the cam 3 b.

Reference numeral 6 is a fixing head opposed to the insertion head 3 viathe board 2. The fixing head 6 cuts and folds the lead wires 100 a ofthe electronic components 100 inserted into the holes 2 a of the board 2and fixes the electronic components 100 to the board 2.

Reference numeral 7 is used as an AC servo motor which is a drivingsource to apply a driving force to the fixing head 6. The AC servo motor7 is directly coupled to a driving shaft 6 a of the fixing head 6. Thedriving shaft 6 a is equipped with an encoder 8 to detect a rotatingposition thereof. The driving shaft 6 a also has a cam 6 b fixedthereto. The cam 6 b, as part of the fixing head 6, is accompaniedduring operation by a driving lever 6 c driving the fixing head 6.

Output signals from the encoder 5 of the insertion head 3 and theencoder 8 of the fixing head 6 are input to a controlling device 10. TheAC servo motor 4 of the insertion head 3 and the AC servo motor 7 of thefixing head 6 are driven synchronously by the controlling device 10.Reference numeral 9 a is a manual handle used for bringing the encoder 5of the insertion head 3 to an origin of the encoder 5 and referencenumeral 9 b is a manual handle for bringing the encoder 8 of the fixinghead 6 to an origin of the encoder 8.

Now the operation will be described. When the insertion head 3 is drivenby a driving force of the AC servo motor 4, the lead wires 100 a of theelectronic component 100 in the component feeding member 1 are separatedfrom the tapes 101 and taken out so that the lead wires 100 a of thecomponent 100 are inserted into the holes 2 a of the board 2.Simultaneously with this, the fixing head 6 is driven by a driving forceof the AC servo motor 7, so that the lead wires 100 a of the electroniccomponent 100 inserted to the holes 2 a of the board 2 are cut andfolded to secure the component 100 to the board 2 as shown in FIG. 7.The insertion head 3 and fixing head 6 are moved by the respective cams3 b and 6 b. The rotation of the AC servo motors 4 and 7 driving thedriving shafts 3 a and 6 a with having the cams 3 b and 6 b arecontrolled in synchronization with each other by the controlling device10 on the basis of output signals from the encoders 5 and 8 directlycoupled to the motors 4, 7. Therefore, the insertion head 3 and fixinghead 6 operate synchronously. The encoders 5, 8 of the insertion head 3and fixing head 6 are brought to their respective origins by thecorresponding manual handles 9 a and 9 b.

In the embodiment, since the driving sources are separately provided forthe insertion head 3 and fixing head 6, the driving motors can be smallin size and a time required to stop and start the motors is reduced.

A second embodiment of the present invention will be discussed withreference to FIGS. 2 and 3. FIGS. 2 and 3 show a fixing head of theembodiment. The component feeding member 1 and the insertion head 3 havethe same constitution as in the first embodiment, and therefore, thedescription and illustration thereof will be abbreviated.

Referring to FIG. 2, a fixing head 11 is constructed by a lifting part12 and a folding part 13 each having a driving source. The lifting part12 is composed of an AC servo motor 14 as the driving source, anactuator 15 constructed by a ball screw converting the rotation of theAC servo motor 14 to the linear motion and a linear guide having highaccuracy, an arm 16 fixedly connected to the actuator 15, and an encoder17 for detecting a rotating position of the AC servo motor 14. Thefolding part 13 comprises of an AC servo motor 18 as a driving source,an actuator 19 constructed by a ball screw converting the rotationalmotion of the AC servo motor 18 to the linear motion and a highlyaccurate linear guide, an arm 20 tightly coupled to the actuator 19, amovable blade 21 interlocking with the arm 20, and an encoder 22 fordetecting a rotating position of the AC servo motor 18. Lead wires of anelectronic component inserted into the board 2 are cut and folded by themovable blade 21, and then the electronic component is fixed to theboard 2. Output signals of the encoders 17 and 22 detecting the rotatingpositions of the AC servo motors 14 and 18, and the output signal of theencoder 5 of the insertion head 3 are input to a controlling device 25.The AC servo motors 14 and 18 of the lifting part 12 and folding part 13of the fixing head 11 are accordingly driven based on the output signalfrom the encoder 5 of the insertion head 3, so that the insertion head3, and the lifting part 12 and the folding part 13 of the fixing head11, are synchronized with one another.

In FIG. 3, a slidable shaft 23 is coupled to the arm 16 to move thelifting part 12 up and down. A shaft 24 for driving the movable blade 21is inserted in the shaft 23 in a slidable fashion and coupled to the arm20.

The operation of the fixing head 11 in the above-described constitutionwill now be described. The rotation of the AC servo motor 14 as adriving source is transmitted to the actuator 15, which converts therotating motion to is the linear motion. The arm 16 and the shaft 23 areinterlocked with the up/down movement of the actuator 15, whereby thefixing head 11 is moved up near the board 2. Then, the rotation of theAC servo motor 18 as a driving source is transmitted to the actuator 19,which converts the rotation to the linear motion, and the arm 20 and theshaft 24 are moved in an interlocking manner with the up/down movementof the actuator 19. As a consequence, the movable blade 21 is moved tocut and fold the lead wires of the electronic component inserted intothe holes of the board 2 by the insertion head 3. The electroniccomponent is fixed to the board 2 in this manner.

In the fixing head 11 of the embodiment, since the lifting part 12 andthe folding part 13 are provided with the AC servo motors 14 and 18,respectively, a moving distance in the up/down direction of the liftingpart 12 and a moving distance of the folding part 13 can be set freely.Moreover, a driving shaft, a cam, a lever, etc. required forinterlocking the parts 12 and 13 can be eliminated, whereby the fixinghead becomes compact in size. Besides, the operation cycle time isshortened with the same driving force.

In the mounting apparatus of the present invention, as is made clearfrom the foregoing description, the insertion head and the fixing headare separately provided with respective driving sources which driveindependently of each other. Therefore, the rotational load and theinertial force of the rotational load of each driving source can bereduced, helping to make the driving motor compact. The apparatus as awhole is thus made compact. Further, the time used to stop and start theapparatus can be shortened, which leads to a decrease of the mountingcycle time. The driving sources can be driven synchronously by thecontrolling device in the simple constitution, and the number ofassembling steps can be reduced.

Since the insertion head and the fixing head are synchronized based onthe output signals of the encoders while the encoder and the drivingmotor are set at the driving shaft of each head, the synchronization canbe achieved with a high reliability in a simple and inexpensivestructure.

When the driving motor and the encoder for detecting the rotatingposition are installed at each of the lifting part and the folding partof the fixing head, the moving distance in the up/down direction of thelifting part and the moving distance of the folding part can be freelyset and, moreover, a driving shaft, a cam, a lever and the like forinterlocking both parts can be eliminated. Accordingly, the apparatusbecomes compact with the operation cycle time reduced with the samedriving force.

The insertion head, and the lifting part and the folding part of thefixing head, are synchronously driven based on the output signal fromthe encoder of the insertion head. The synchronization can be realizedwith a high reliability in a simple construction.

Although the present invention has been fully described in connectionwith the preferred embodiments thereof and with reference to theaccompanying drawings, it is to be noted that various changes andmodifications are apparent to those skilled in the art. Such changes andmodifications are to be understood as included within the scope of thepresent invention as defined by the appended claims unless they departtherefrom.

What is claimed is:
 1. An apparatus for mounting electronic components,said apparatus comprising: an electronic component feeding member forfeeding electronic components having lead wires that are bonded withtapes; an insertion head for inserting lead wires of one of theelectronic components fed from the feeding member into holes of a boardafter being separated from the tapes; a driving source connected to saidinsertion head; a fixing head facing said insertion head, said fixinghead including a lifting part, a lifting part driving source, a foldingpart, and a folding part driving source; means for providing outputsignals corresponding to positions of each of said driving sources; anda synchronizing device connected to said driving sources and said meansfor providing output signals for synchronizing said driving sourcesbased on said output signals therefrom such that said insertion head,said lifting part, and said folding part are synchronized with eachother.
 2. The apparatus of claim 1, wherein the synchronizing devicesynchronizes said driving sources from the output signals therefrom suchthat said insertion head, said lifting part and said folding part aresynchronized with each other so that said insertion head is driven bysaid respective driving source so as to separate the lead wires of theelectronic component in said component feeding member from the tapes andso as to take out the separated lead wires so that the lead wires of thecomponent are inserted into the holes of the board, and simultaneously,said lifting part and said folding part of said fixing head are drivenby said respective driving sources so as to cut the lead wires of theelectronic component inserted into the holes of the board and fold thelead wires to secure the component to the board.
 3. The apparatus ofclaim 1, wherein said insertion head driving source comprises a motor,said lifting part driving source comprises a motor, and said foldingpart driving source comprises a motor.
 4. The apparatus of claim 2,wherein said means for providing output signals comprises a plurality ofencoders connected to said motors, respectively, wherein said liftingpart and said folding part of said fixing head are driven based on theoutput signal from said encoder of said insertion head.
 5. The apparatusof claim 4, wherein the synchronizing device synchronizes said drivingmotors from the output signals therefrom such that said insertion headand said lifting part and said folding part of said fixing head aresynchronized with each other so that said insertion head is driven bysaid respective driving motor so as to separate the lead wires of theelectronic component in said component feeding member from the tapes andso as to take out the separated lead wires so that the lead wires of thecomponent are inserted into the holes of the board, and simultaneously,said lifting part and said folding part of said fixing head are drivenby said respective driving motors so as to cut the lead wires of theelectronic component inserted into the holes of the board and fold thelead wires to secure the component to the board.
 6. An apparatus formounting electronic components, said apparatus comprising: an electroniccomponent feeding member for feeding electronic components having leadwires bonded to tapes; an insertion head for inserting lead wires of oneof the electronic components fed from said electronic component feedingmember into holes of a board after being separated from the tapes; afirst driving source connected to said insertion head; a first encoderfor detecting a position of said first driving source and producing anoutput signal indicative of the detected position; a fixing head facingsaid insertion head, said fixing head including a lifting assembly, asecond driving source connected to said lifting assembly, a foldingassembly, and a third driving source connected to said folding assembly;a second encoder for detecting a position of said second driving sourceand producing an output signal indicative of the detected position; athird encoder for detecting a position of said third driving source andproducing an output signal indicative of the detected position; and asynchronizing device, connected to said first, second and third drivingsources and said first, second and third encoders, for synchronizingsaid driving sources based on the output signals therefrom such that theoperation of said insertion head, said lifting assembly, and saidfolding assembly are synchronized.
 7. The apparatus as claimed in claim6, wherein each of said first, second and third driving sourcescomprises an AC servo motor.
 8. The apparatus as claimed in claim 7,wherein said lifting assembly comprises an actuator connected to saidsecond AC servo motor for converting rotation of said motor to linearmotion, and an arm fixedly connected to said actuator, wherein saidsecond encoder is operable to detect a rotary position of said second ACservo motor.
 9. The apparatus as claimed in claim 8, wherein saidfolding assembly comprises an actuator connected to said third AC servomotor for converting rotation of said motor to linear motion, and an armcoupled to said actuator, a movable blade interlocked with said arm,wherein said third encoder is operable to detect a rotary position ofsaid third AC servo motor.